Quantum interference in spontaneous emission from a V-type three-level atom in photonic crystals

TL;DR

This paper investigates how quantum interference affects spontaneous emission in a V-type three-level atom within photonic crystals, revealing controllable emission rates through detuning and initial state phase adjustments.

Contribution

It provides an analytical framework for understanding and controlling spontaneous emission and quantum interference in three-level atoms embedded in photonic crystals.

Findings

Identification of three dynamic regimes: non-Markovian decay, damped interference, and quantum interference.

Maximum quantum interference occurs when the atom's excited states are degenerate.

Spontaneous emission rates can be controlled by detuning and initial state phase.

Abstract

Studying the spontaneous emission of a V-type three-level atom embedded in a photonic crystal (PC) by fractional calculus, we found that the atomic excited states in the anisotropic PC can be expressed as a superposition of four dressed states analytically. Through detuning two allowed atomic transition energies with respect to the photonic band edge, the coupling between these two transitions leads to three dynamic regimes, namely non-Markovian decay, damped quantum interference and quantum interference, classified by the numbers of contributed bounded dressed states. From the degree of quantum interference of two atomic transitions, we found the energy exchange between the atom and PC reservoir is the lowest as the excited states become degenerate but with maximum quantum interference when the atom is prepared at one of the excited states. The results also show that excited states prefer to stay out of phase at all detuning energy except for near degenerate. Therefore, we can control the spontaneous emission rate not only by the amount of detuning frequencies but also the relative phase of initial states.